Buffering data in a parallel processing environment

ABSTRACT

An integrated circuit includes a plurality of tiles. Each tile comprises a processor; a switch including switching circuitry to forward data over data paths from other tiles to the processor and to switches of other tiles; a first buffer that stores data from the switch; a memory accessible to the processor; a second buffer that stores a plurality of data words retrieved from the memory; and a multiplexer that selectively provides data to the processor from the first buffer or the second buffer based on a refill signal.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No.60/665,563 filed Mar. 25, 2005, and U.S. Provisional Application No.60/750,149 filed Dec. 13, 2005, both of which are incorporated herein byreference.

This application is also related to U.S. application Ser. No.11/314,254, titled “MANAGING DATA FLOWS IN A PARALLEL PROCESSINGENVIRONMENT,” U.S. application Ser. No. 11/314,861, titled “TRANSFERRINGDATA IN A PARALLEL PROCESSING ENVIRONMENT,” U.S. application Ser. No.11/313,895, titled “FLOW CONTROL IN A PARALLEL PROCESSING ENVIRONMENT,”U.S. application Ser. No. 11/314,270, titled “MANAGING BUFFER STORAGE INA PARALLEL PROCESSING ENVIRONMENT,” each of which is being filedconcurrently with the present application, and each of which is alsoincorporated herein by reference.

BACKGROUND

The invention relates to integrated circuits, and more particularly tobuffering data in a parallel processing environment.

FPGAs (Field Programmable Gate Arrays) and ASICs (Application SpecificIntegrated Circuits) are two exemplary approaches for implementingcustomized logic circuits. An ASIC is designed for a specificapplication. The cost of building an ASIC includes the cost ofverification, the cost of physical design and timing closure, and theNRE (non-recurring costs) of creating mask sets and fabricating the ICs.Due to the increasing costs of building an ASIC, FPGAs became popular inthe late 1990's. Unlike an ASIC, an FPGA is reprogrammable, in that itcan be reconfigured for each application. Similarly, as protocolschange, an FPGA design can be changed even after the design has beenshipped to customers, much like software can be updated. However, FPGAsare typically more expensive, often costing 10 to 100 times more than anASIC. FPGAs are typically power hungry and their performance can be 10to 20 times worse than that of an ASIC.

The MIT Raw integrated circuit design is an example of a tiledintegrated circuit with a computational substrate that providesreconfigurability of an FPGA along with the performance and capabilityof an ASIC, described, for example, in “Baring It All to Software: RAWMachines” IEEE Computer, September 1997, pp. 86-93.

SUMMARY

In one aspect, in general, the invention features an integrated circuitincluding a plurality of tiles. Each tile comprises a processor; aswitch including switching circuitry to forward data over data pathsfrom other tiles to the processor and to switches of other tiles; afirst buffer that stores data from the switch; a memory accessible tothe processor; a second buffer that stores a plurality of data wordsretrieved from the memory; and a multiplexer that selectively providesdata to the processor from the first buffer or the second buffer basedon a refill signal.

This aspect of the invention can include one or more of the followingfeatures.

The memory can be internal to the tile or external to the tile.

The tile is configured to load the second buffer with additional dataretrieved from the memory after the multiplexer provides data stored inthe second buffer to the processor.

The tile is configured to load the second buffer with additional dataretrieved from the memory after the second buffer becomes empty.

An interrupt to the processor is triggered when the second bufferbecomes empty.

The tile is configured to set the value of the refill signal so that themultiplexer provides the processor data from the first buffer inresponse to the second buffer providing a last data value retrieved fromthe memory.

The tile is configured to set the value of the refill signal so that themultiplexer provides the processor data from the second buffer inresponse to the first buffer overflowing to the memory.

In another aspect, in general, the invention features a method fortransmitting data in an integrated circuit, the integrated circuitcomprising a plurality of tiles, each tile comprising a processor, and aswitch including switching circuitry to forward data over data pathsfrom other tiles to the processor and to switches of other tiles. Themethod comprises storing data from the switch in a first buffer; storinga plurality of data words retrieved from a memory accessible to theprocessor in a second buffer; and selectively providing data to theprocessor from the first buffer or the second buffer based on a refillsignal.

This aspect of the invention can include one or more of the followingfeatures.

The plurality of data words are retrieved from a memory internal to thetile.

The plurality of data words are retrieved from a memory external to thetile.

The method further comprises loading the second buffer with additionaldata retrieved from the memory after the multiplexer provides datastored in the second buffer to the processor.

The method further comprises loading the second buffer with additionaldata retrieved from the memory after the second buffer becomes empty.

The method further comprises triggering an interrupt to the processorwhen the second buffer becomes empty.

The method further comprises setting the value of the refill signal sothat the multiplexer provides the processor data from the first bufferin response to the second buffer providing a last data value retrievedfrom the memory.

The method further comprises setting the value of the refill signal sothat the multiplexer provides the processor data from the second bufferin response to the first buffer overflowing to the memory.

Aspects of the invention can have one or more of the followingadvantages.

Buffer virtualization enables a network to avoid and/or recover fromdeadlock by providing storage space for overflow data that does not fitinto buffers in the switches. A multiplexer selectively providing datafrom an input buffer or an overflow buffer storing values that haveoverflowed to memory provides a consistent interface for the networkswhether the data is coming from the network input buffers or frommemory. A flow control technique can be used to limit the amount ofstorage space used for overflow data.

Other features and advantages of the invention will become apparent fromthe following description, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram of a tiled integrated circuit.

FIG. 2A is a block diagram of a tile.

FIG. 2B is a block diagram of a pipeline.

FIGS. 3A-3C are block diagrams of switching circuitry.

FIG. 4 is a flowchart for a compiling process.

FIGS. 5A-5F are block diagrams showing reconfigurable logic in theintegrated circuit.

FIG. 6A is a block diagram of a VLIW processor.

FIG. 6B is a block diagram of a multithreaded processor.

FIG. 6C is a block diagram of a VLIW switch processor.

FIG. 6D is a block diagram of a multithreaded switch processor.

FIG. 7 is block diagram of a route through an array of tiles.

FIG. 8 is block diagram of switching circuitry.

FIG. 9 is a diagram of a communication pattern in an array of tiles.

FIG. 10 is a block diagram of a dynamic network virtualized buffer.

FIG. 11 is a block diagram of a sorting module.

FIG. 12 is a diagram of a tagged packet.

FIGS. 13A and 13B are graphs representing communicating processes.

DESCRIPTION 1 Tiled Circuit Architecture Overview

Referring to FIG. 1, an integrated circuit 100 (or “chip”) includes anarray 101 of interconnected tiles 102. Each of the tiles 102 is afunctional unit that includes a processor and a switch that forwardsdata from other tiles to the processor and to switches of other tilesover data paths 104. The switch is coupled to the processor so that datacan be sent to or received from processors of other tiles. Theintegrated circuit 100 includes other on-chip circuitry such asinput/output (I/O) interface circuitry to couple data in and out of thecircuit 100, and clock distribution circuitry to provide clock signalsto the processors of the tiles.

The integrated circuit 100 shown in FIG. 1 includes a two-dimensionalarray 101 of rectangular tiles with data paths 104 between neighboringtiles to form a mesh network. The data path 104 between any two tilescan include multiple wires to support parallel channels in eachdirection. Optionally, specific sets of wires between two tiles can bededicated to different mesh networks that can operate independently.Alternative network configurations include networks having paths thatextend to diagonal neighbors or to tiles that are multiple rows orcolumns away. Other configurations include higher dimensional meshtopologies. For example, multiple layered integrated circuits or otherthree-dimensional configurations can be used to form networks in whichthe connections form a cube of network nodes.

The data paths 104 from one or more tiles at the edge of the network canbe coupled out of the array of tiles 101 (e.g., over I/O pins) to anon-chip device 108A, an off-chip device 108B, or a communication channelinterface 108C, for example. Multiple wires of one or more parallelchannels can be multiplexed down to a fewer number of pins or to aserial channel interface. For example, the wires for one or morechannels can be multiplexed onto a high-speed serial link (e.g., SerDes,SPIE4-2, or SPIE5) or a memory controller interface (e.g., a memorycontroller for DDR, QDR SRAM, or Dynamic RAM). The memory controller canbe implemented off-chip or in logic blocks within a tile or on theperiphery of the integrated circuit 100.

The following exemplary implementations are described in the context oftiles that have the same structure and functionality. Alternativelythere can be multiple “tile types” each having different structureand/or functionality. For example, tiles that couple data off of theintegrated circuit 100 can include additional circuitry for I/Ofunctions.

Referring to FIG. 2A, a tile 102 includes a processor 200, a switch 220,and sets of incoming wires 104A and outgoing wires 104B that form thedata paths 104 for communicating with neighboring tiles. The processor200 includes a program counter 202, an instruction memory 204, a datamemory 206, and a pipeline 208. Either or both of the instruction memory204 and data memory 206 can be configured to operate as a cache foroff-chip memory. The processor 200 can use any of a variety of pipelinedarchitectures. The pipeline 208 includes pipeline registers, functionalunits such as one or more arithmetic logic units (ALUs), and temporarystorage such as a register file. The stages in the pipeline 208 include,for example, instruction fetch and decode stages, a register fetchstage, instruction execution stages, and a write-back stage. Whether thepipeline 208 includes a single ALU or multiple ALUs, an ALU can be“split” to perform multiple operations in parallel. For example, if theALU is a 32-bit ALU it can be split to be used as four 8-bit ALUs or two16-bit ALUs. The processor 200 can include other types of functionalunits such as a multiply accumulate unit, or a vector unit. Theprocessor 200 can be multithreaded and/or have capabilities of a VeryLong Instruction Word (VLIW) processor, a superscalar processor, or avector processor.

The switch 220 includes input buffers 222 for temporarily storing dataarriving over incoming wires 104A, and switching circuitry 224 (e.g., acrossbar fabric) for forwarding data to outgoing wires 104B or theprocessor 200. The input buffering provides pipelined data channels inwhich data traverses a path 104 from one tile to a neighboring tile inpredetermined number of clock cycles (e.g., a single clock cycle). Thispipelined data transport enables the integrated circuit 100 to be scaledto a large number of tiles without needing to limit the clock rate toaccount for effects due to wire lengths such as propagation delay orcapacitance. (Alternatively, the buffering could be at the output of theswitching circuitry 224 instead of, or in addition to, the input.)

1.1 Switch Operation

A tile 102 controls operation of a switch 220 using either the processor200, or separate switch processor dedicated to controlling the switchingcircuitry 224. Separating the control of the processor 200 and theswitch 220 allows the processor 200 to take arbitrary data dependentbranches without disturbing the routing of independent messages passingthrough the switch 220.

In some implementations, the switch 220 includes a switch processor thatreceives a stream of switch instructions for determining which input andoutput ports of the switching circuitry to connect in any given cycle.For example, the switch instruction includes a segment or“subinstruction” for each output port indicating to which input port itshould be connected. In other implementations, the processor 200receives a stream of compound instructions with a first instruction forexecution in the pipeline 208 and a second instruction for controllingthe switching circuitry 224.

The switch instructions enable efficient communication among the tilesfor communication patterns that are known at compile time. This type ofrouting is called “static routing.” An example of data that wouldtypically use static routing are operands of an instruction to beexecuted on a neighboring processor.

The switch 220 also provides a form of routing called “dynamic routing”for communication patterns that are not necessarily known at compiletime. In dynamic routing, circuitry in the switch 220 determines whichinput and output ports to connect based on header information in thedata being dynamically routed. A tile can send a message to any othertile by generating the appropriate address information in the messageheader. The tiles along the route between the source and destinationtiles use a predetermined routing approach (e.g., shortest ManhattanRouting). The number of hops along a route is deterministic but thelatency depends on the congestion at each tile along the route. Examplesof data traffic that would typically use dynamic routing are memoryaccess traffic (e.g., to handle a cache miss) or interrupt messages.

The dynamic network messages can use fixed length messages, or variablelength messages whose length is indicated in the header information.Alternatively, a predetermined tag can indicate the end of a variablelength message. Variable length messages reduce fragmentation.

The switch 220 can include dedicated circuitry for implementing each ofthese static and dynamic routing approaches. For example, each tile hasa set of data paths, buffers, and switching circuitry for staticrouting, forming a “static network” for the tiles; and each tile has aset of data paths, buffers, and switching circuitry for dynamic routing,forming a “dynamic network” for the tiles. In this way, the static anddynamic networks can operate independently. A switch for the staticnetwork is called a “static switch”; and a switch for the dynamicnetwork is called a “dynamic switch.” There can also be multiple staticnetworks and multiple dynamic networks operating independently. Forexample, one of the dynamic networks can be reserved as a memory networkfor handling traffic between tile memories, and to/from on-chip oroff-chip memories. Another network may be reserved for data associatedwith a “supervisory state” in which certain actions or resources areareserved for a supervisor entity.

As described above, the switch 220 is coupled to the processor 200 overprocessor coupling wires 230. For fast (e.g., low latency) communicationbetween tiles of neighboring processors, the coupling wires 230 can beintegrated directly into the pipeline 208. The processor 200 cancommunicate with the switch 220 using distinct opcodes to distinguishbetween accesses to the static and dynamic network ports. Alternatively,the instructions can use register names to refer to switch ports.

For example, the processor can send or receive data by writing to orreading from a register interface that is directly mapped to the inputbuffers 222 of the switch 220. For data going to or coming from theprocessor 200, a switch instruction indicates that the switch 220 shouldcouple data to or from a selected register or bypass path of thepipeline 208 over a register mapped pipeline integrated switch interface232. This pipeline integration allows data to be available to the switch200 the moment an instruction is executed and the register value isavailable. In the next cycle the same data could appear at an inputbuffer of another tile.

Referring to FIG. 2B, a register mapped pipeline integrated switchinterface 232 includes a set of multiplexers 232A and output buffers232B coupled to different output ports of the static or dynamic switch.The switch interface also includes a set of multiplexers 232C thatselect data from a register file 236 or any of a set of input buffers232D coupled to different input ports of the static or dynamic switch.The multiplexers 232C feed the inputs to logic units 240A and 240B. Theoutput buffers 232B and input buffers 232D are mapped to the name spaceof the register file 236. When the processor 200 reads from a registername mapped to a given switch port, data is taken from the correspondinginput buffer 232D. When the processor 200 writes to a register namemapped to a given switch port, data is inserted into the correspondingoutput buffer 232B. The multiplexers 232A are able to select data fromany pipeline stage (e.g., before or after the logic units 240A and 240B,or before or after functional units 242A and 242B) as soon as the valueis available. If the processor 200 loads an instruction to read from anempty input buffer 232D or to write to a full output buffer 232B, theprocessor 200 will stall until it is able to proceed.

Referring to FIG. 3A, switching circuitry 224A includes fivemultiplexers 300N, 300S, 300E, 300W, 300P for coupling to the northtile, south tile, east tile, west tile, and local processor 200,respectively. Five pairs of input and output ports 302N, 302S, 302E,302W, 302P are connected by parallel data buses to one side of thecorresponding multiplexer. The other side of each multiplexer isconnected to the other multiplexers over a switch fabric 310. Inalternative implementations, the switching circuitry 224 additionallycouples data to and from the four diagonally adjacent tiles having atotal of 9 pairs of input/output ports. Each of the input and outputports is a parallel port that is wide enough (e.g., 32 bits wide) tocouple a data word between the multiplexer data bus and the incoming oroutgoing wires 104A and 104B or processor coupling wires 230.

A control module 304 selects which input port and output port areconnected in a given cycle. The routing performed by the control module304 depends on whether the switching circuitry 224 is part of thedynamic network or static network. For the dynamic network, the controlmodule 304 includes circuitry for determining which input and outputports should be connected based on header information in the incomingdata.

Referring to FIG. 3B, for the static network, the control module 304A ofswitching circuitry 224A includes a switch instruction memory 306storing switch instructions that indicate which input and output portsshould be connected. A switch instruction stored in the switchinstruction memory 306 includes a subinstruction for each output port(in this case, five subinstructions). Each subinstruction represents amultiplexer select value which routes one of five input ports to thecorresponding output port.

A program counter 308 steps through the switch instructions,interpreting control information (e.g., a condition code) in the switchinstructions to perform actions such as branches or jumps based onprogram control flow. In a given clock cycle, the control module 304Acan enable the multiplexers to move data independently onto any outputport from any input port, including multicasting an input port to alloutput ports, as long as two input ports are not connected to the sameoutput port in the same clock cycle.

The control module 304A is able to function as a switch processor withor without an ALU and registers. The control module 304A can include anALU and registers to allow in-switch processing of in-flight messages.Optionally, the control module 304A can include other components such asa floating point arithmetic unit, or bit shifter, for example, toperform additional functions. The control module 304A can also beVLIW-type processor and be multithreaded.

Referring to FIG. 3C, a static network switch 320 is configured in“single instruction mode.” In single instruction mode, one instructionis used to control the multiplexers of the switch over many cycles. Whendata arrives at one switch input port, that data is routed according tothe instruction stored in the single instruction buffer 322 independentof the availability of data a the other switch input ports. In thisexample, the switch 320 includes multiplexers 324 for turning singleinstruction mode on or off. The control signals for the multiplexers 324are controlled by the processor 200 (e.g., mapped to a register namespace of the processor 200).

When single instruction mode is on, data is routed according to thesingle instruction buffer 322. When single instruction mode is off, datais routed according to instructions in the switch instruction buffer346. To save power in single instruction mode, switches are able to turnoff circuitry such as a switch instruction fetch unit, and a switchinstruction decode logic. Power can also be saved by reducing the sizeof the single instruction buffer 322 (e.g., to the size of a singleinstruction). In some implementations the size of the single instructionbuffer 322 can be reduced to only enough bits to represent the couplingbetween the input and output ports (e.g., 2, 3, or 4 bits).

When utilizing single instruction mode, the individual output directionsare independent of each other and there are no synchronizationrequirements. For example, if the single instruction specifies a routefrom north to south and a route from east to west, and data arrives onthe east port, but no data arrives on the north port, the switch willroute the data from east to west independent of data being available onthe north or ports. With multiple static switches configured to usesingle instruction mode, the static network can be utilized to constructa dedicated physical channel across the integrated circuit.

The switches 220 include hardware and software mechanisms for providingflow control to ensure that data arriving at a full tile input bufferdoes not overwrite old data still pending in the buffer or causedeadlock. A switch 220 can include circuitry to detect full/empty statesof buffers, and some of the wires in the data paths 104 of the static ordynamic network can be dedicated to communicating flow controlinformation. In the dynamic network, the traffic patterns areunpredictable and there is a need for techniques for deadlock avoidanceor deadlock detection and recovery. For example, buffers that becomefull can be overflowed into memory coupled to the switch 220 or theprocessor 200, or over one of the networks to off-chip memory. In thestatic network, the traffic patterns are controlled by the processing ofswitch instructions in a way that ensures correct delivery of data andavoids deadlock.

In a first approach to flow control for the static network, a processor200 or switch 220 stalls if it is executing an instruction that attemptsto read data from an empty input buffer 222 or from an empty processoroutput buffer 236, or send data to a tile with a full input buffer 222.This approach ensures correctness in the presence of timing variationsintroduced by dynamic events such as dynamic memory references and I/Ooperations.

In a second approach to flow control for the static network, the switch220 can continue to process subinstructions of a macro switchinstruction if data has arrived at the corresponding input buffers, anddelay processing subinstructions if the corresponding input buffer isempty. The switch 220 is also notified that an input buffer at aconnected tile that receives data from a given output port is full(e.g., via a full/empty bit). The switch 220 is able to continueprocessing switch instructions for other output ports while suspendingonly that output port.

In one implementation of this second approach, there is a switchinstruction memory 306 (e.g., separate memory units or separate queueswithin a single memory unit) and program counter 308 for each outputport to enable the switch 220 to operate independently on a separatestream of switch instructions for respective output ports. For example,the switch 220 can extract the instruction streams for respective outputports from an incoming macro switch instruction stream that includessubinstructions for the respective output ports. The condition code froma macro switch instruction can be included with each correspondingsubinstruction of the extracted instruction streams. Alternatively, eachsubinstruction can include its own condition code based on theappropriate program logic. This second approach allows data that can beforwarded without sacrificing correctness to be forwarded withoutfurther delay.

1.2 Additional Circuitry

A tile can include additional circuitry embedded within or coupled tothe processor 200 and/or switch 220. The configuration of the circuitryin a tile can be controlled by local control information stored in thetile. For example, a module in the tile can be turned on or off orconfigured into a variety of modes based on the state of a “modeindicator” (e.g., one or more bits) stored in a register or other memorystore.

A tile 102 can include various types of memory modules to serve as theinstruction memory 204, data memory 206, or as a local memory store forother types of information such as control information for the tile.There can be a small SRAM bank in each tile in addition to a large SRAMbank. There can also be a larger DRAM bank in each tile. Each tile canhave mode indicators used to select among these banks. Any of the memorymodules can be treated as a cache for a larger memory store outside thetile 102 or the integrated circuit 100. Such external memory (e.g.,DRAM) is accessible over high bandwidth paths of one or more dynamicnetworks. The amount of memory can be chosen to roughly balance theareas devoted to processing and memory, and to match the memory accesstime and the processor clock.

A tile 102 can include Reconfigurable Logic (RL) that takes operandsfrom registers and writes them back to registers after performingreconfigurable logic operations. The RL can be used for bit-level (or“gate-level”) logic, and also for multi-bit-level (e.g., byte-level)logic. The operations performed by the RL can be specified bylogic-level instructions supplied to the RL.

Functions such as virtual address translation, caching, global sharedmemory and memory protection can be implemented by any combination ofhardware and software (e.g., processor instructions). A tile 102 caninclude a translation look-aside buffer (TLB) to translate virtualaddresses as they come out of the processor 200 on each tile 102. A modebit can turn off translation. The events such as cache miss ortranslation fault can trigger a trap or interrupt to the processor 200,so that the processor 200 can handle it in software. For example, therecan be multiple trap lines to the processor 200. Alternatively, thereare few trap lines, but there is a trap vector that the processor 200can access which encodes the type of trap that occurred. There is a modeindicator which can allow selecting whether the software or the hardwarehandles these events. A hardware cache tag file can export a hit/missstatus to the software rather than stalling the processor pipeline.

In a processor 200 in which the switch 220 is integrated into the bypasspaths of the processor pipeline 208, the translation is performed beforethe data is sent (or committed) to the switch (e.g., before beingwritten into a switch buffer to be sent out on any one of the static ordynamic networks). In this way, if there is a translation fault, thenthe data is not sent and the instruction can be safely aborted.Otherwise, data for which there has been a translation fault couldcorrupt program execution if sent over a network.

2 Tiled Circuit Programming Overview

A software system for the tiled integrated circuit 100 includes acompiler that is able to schedule instructions in both time and space bygenerating both processor and switch instructions for arranging thestatic network. The compiler can also prepare messages to be sent overthe dynamic network. The combination of the static network and thepipeline integration enables the compiler to orchestrate a calculationto be performed over multiple tiles with fast register-levelcommunication between tiles. The software system can exploit bothcoarse-grained parallelism and fine-grained Instruction-LevelParallelism (ILP). In addition, the software system can exploitreconfigurable logic in each tile to construct operations that areuniquely suited for a particular application. This reconfigurable logiccan be coded in a hardware description language such as verilog or VHDL,or in a high-level language such as C.

The operating system (OS) for the integrated circuit 100 can include aLinux-like kernel or a similar kernel running on a single tile 102.Alternatively, the OS can be a distributed OS running on multiple tilessending messages to each of the processes on each of the tiles.

The compiler can leverage the architectural features of the integratedcircuit 100 by partitioning and scheduling ILP or data-level parallelismacross the tiles. The compiler is able to automatically parallelizesequential applications across multiple tiles 102. For example, outerloops can be parallelized at a coarse-grained while inner loops can beparallelized at a fine grain, much as in a vectorizing compiler. Whenthe compiler can identify commonly occurring instruction patterns or bitoperations, they can be configured into special operations that will runin a single cycle using the reconfigurable logic.

Referring to FIG. 4, a compiling process 400 includes a number ofstages. The compiler identifies and partitions for fine grain ILP inprogram by balancing the benefits of parallelism versus the overheads ofcommunication and synchronization. In a partitioning phase 402, thecompiler generates parallel code for a number of threads up to thenumber of tiles in the integrated circuit 100. In the partitioning phase402, the compiler assumes an idealized fully-connected switch (an “idealcrossbar”), an unbounded number of virtual registers per tile, andsymbolic data references. In a placement phase 404, the compiler removesthe idealization of an ideal crossbar by selecting a one-to-one mappingfrom threads to physical tiles. The placement algorithm attempts tominimize a latency and bandwidth cost measure and can be, e.g., avariant of a VLSI cell placement algorithm. In a routing and globalscheduling phase 406, the compiler allocates physical network resourceswith the goal of minimizing the overall estimated completion time of theprogram. The compiler output includes a program (e.g., a stream ofinstructions) for the processor 200 of each participating tile.

In an optional configuration phase 408, the compiler selects anapplication-specific configuration for reconfigurable logic to performone or more custom operation. For each custom operation, theconfiguration compiler generates logic-level instructions for thereconfigurable logic and if necessary rewrites associated processor orswitch instructions. For example, a compound operation involvingmultiple instructions is replaced by a call to the appropriate custominstruction using the reconfigurable logic. The compiler output includesa program (e.g., a stream of instructions) for each tile processor 200and switch 220, and optional logic-level instructions.

Alternatively, the compiler can generate logic-level instructions basedon a separate hardware description language program, as described inmore detail below.

3 Additional Features

3.1 Operand Decoupling

As described above, in a first approach to flow control for the staticnetwork, a processor 200 or switch 220 stalls until all data to beswitched according to a macro switch instruction become available beforethey are forwarded to their respective output ports. This approach cancause starvation at some ports where data, such as an operand for aprocessor instruction to be executed in another tile, is available butis not able to make forward progress.

Under certain circumstances, it is a better to allow the input port (oroutput port) buffers to be decoupled from each other so that each outputport can route an operand as soon as the operand is available. Asdescribed above, in a second approach to flow control for the staticnetwork, there is a switch instruction memory 306 and program counter308 for each output port to enable the switch 220 to operateindependently (e.g., at different rates) on a separate stream of switchinstructions for respective output ports.

Under other circumstances, it is dangerous to allow an operand to beallowed to be routed without all operands to be available for all outputports. In certain of these dangerous scenarios, the program order can beviolated if operands are allowed to bypass each other, resulting infaulty program execution. This is particularly true when runningprograms compiled using an ILP compilation strategy. In ILP compilation,individual instructions that can run in parallel are executed indifferent tiles, and operand values are communicated between tiles. Theorder in which operand values reach input buffers is critical to thecorrectness of the program. Often, only the compiler can make such adetermination at compile time.

One way to solve this problem is to enable the switch 220 to operate inan “operand decoupling mode” in which the switch instruction streams areprocessed synchronously. For example, the mode can be controlled using amode indicator called the Operand Decoupling mode indicator (or the ODmode indicator) that allows the switch 220 to decouple the input buffersin a switch from each other. If this mode indicator is set, then theinput buffers are decoupled, and the switch 220 will allow the operandsto pass each other. For example, in a group of operands that have beenscheduled by the compiler to be switched at the same time (e.g., in thesame cycle), some of the operands can be switched before others. If thebit is not set, then the switch 220 processes switch instructionssynchronously (in “coupled mode”), stalling if necessary until alloperands scheduled to be switched together are available in the inputbuffers.

The switch 220 (or processor 200) can set the OD mode indicator based onthe presence or absence of a tag in the operands. The compiler tagsoperands that must all appear at the switch input buffers before any isrouted with a tag (e.g., a “sequence tag”). All operands that have beentagged as a group have to become available before any is allowed toproceed. The OD mode indicator can be set (directly, or in response to asequence tag in the data) by an application, by the compiler, by thefirmware implemented on the chip, or by a user. The OD mode indicatorcan also be set over a network (e.g., via the dynamic network). The ODmode indicator can be set once at the beginning of execution, or at thetime of shipment of the chip, or at the time of shipment of the systemin which the chip is embedded. An OD mode indicator can be provided perswitch, per tile, or for the entire chip.

3.2 Pipeline Integration

Bypass paths in pipelines short circuit values from one pipeline stageto another without the need to transmit the values to the register fileor to memory each time. The bypass paths in a processor are thuscritical resources for shuttling values around between various stagessuch as ALUs, register files, load-store queues, writeback stages, andso on. As described above, a register mapped interface is able tointegrate the switch 220 into the bypass paths of the processor pipeline208. Register mapped interfaces allow the processor 200 to use registernames to refer to buffers that couple data into or out of the static ordynamic networks. Values may be coupled from a processor bypass path toa switch output port, or values may be read from the switch into theprocessor bypass paths.

Integration of the switch 220 into the bypass paths of the pipeline 208enables the values that are destined to the switch 220 from theprocessor 200 to be picked directly from the processor pipeline 208 assoon as they are produced. For example, data values from the pipeline208 can be sent to switch buffers 232B directly from the processor'sbypass paths, even before the values are written to the register file236 (FIG. 2B) at a writeback stage.

If values going to the network are ordered, care should be taken whenchoosing which value to forward to the network in any given cycle. If“long-latency” instruction that requires the whole pipeline to computewrites to the network, and it is followed by a “short-latency”instruction that also writes to the network, but requires fewer pipelinestage to compute, then to preserve ordering of values to the network,the value from the short-latency instruction is delayed from reachingthe network until the long-latency instruction has written to thenetwork. Control logic is used to determine which value in the pipelinethat targets the network is the oldest to preserve ordering of valuesgoing to the network. It is possible to use a reordering buffer or aunordered network to relax this strict ordering requirement.

The pipeline integrated switch enables a value computed by an ALU of agiven tile to be used as an operand in a neighboring tile's ALU withextremely low latency, e.g., in 1 to 3 cycles, as opposed to 5 or 10cycles, which would be the case if the value was picked from thepipeline in the writeback stage of the pipeline. This low latencytransfer of single word operands between tiles is an important aspect ofenabling an ILP (instruction level parallelism) compiler to compileprograms written in sequential C, C++ or other high level languages tomultiple tiles.

Register file size can be increased from the size used by otherprocessors (which may have 8 to 32 registers), for example, to 64 ormore registers, because some of the register name space is used up toname switch buffers.

In VLIW processors, multiple subinstructions in a macroinstruction mayattempt to read or write to the switch buffers. If multiplesubinstructions in a macroinstruction try to write to a register namemapped to the same switch buffer, there is a conflict. The compileravoids such conflicts in scheduling the VLIW instructions.Alternatively, hardware can be present in the tile to serialize the twowrites into the switch buffers allowing both to take place sequentiallywithout a conflict. Multiple instructions in a macroinstruction are ableto read from the same switch buffer without a conflict.

When an outgoing value is coupled from the processor 200 to the switch220, the processor instruction may include a switch register specifierdenoting one of several output registers. The specified output registermay be linked to a static coupled switch (with the OD mode indicator setto coupled mode), a static decoupled switch (with the OD mode indicatorset to operand decoupling mode), or to a dynamic network switch.

For increased speed, the switch register specifier is able to directlyspecify a register of a neighboring processor. A direct name identifyingthe register can be included, or there can be a directional modeindicator in the instruction that allows the register name to beinterpreted based on the name space of a neighboring tile. For example,a directional mode indicator can be 2 bits corresponding to a registerin a tile in the east, west, north, or south direction. Directional modeindicators allow the name space of a register specifier to be inferredto be that of a neighboring tile. Particularly for a slow clockedsystem, it is useful to avoid a multi-hop near neighbor latency by usinga directional mode indicator to enable a single-hop communication eventfrom one tile to a neighboring tile.

Alternatively, instead of sending a processor value to a register on thesame tile using a register specifier, or to a neighboring or othertile's register or ALU, a processor value can be sent to a memory usinga memory specifier, or to an I/O port using an I/O specifier.

When an incoming value is coupled from the switch to the processor, theprocessor instruction may include a register specifier denoting one ofseveral input registers from the switch. These input registers serve tosynchronize the processor pipeline with the switch even if the switch isrunning in decoupled mode. There can be more input ports than just the 4directions (north, south, east, and west). For example, there can bemultiple networks, and there can also be communication paths forming“hyperlinks” that skip multiple tiles.

Another mode indicator called the Processor Switch Coupling (PSC) modeindicator indicates whether program counters of the processor 200 andswitch 220 are to be coupled. If this PSC mode indicator is set, theprocessor and the switch program counters are coupled and the two areincremented synchronously. For example, both the processor and switchpipelines are stalled if either is stalled.

It is useful for some of these mode indicators, in particular, thedirectional mode indicators, to be linked to the clock speed of theintegrated circuit 100. For example, a given mode may be moreappropriate for a given clock speed. In some cases, a tile is allowed totransfer data over hyperlinks to non-neighbor processors (e.g., byallowing a compiler to have visibility of the hyperlinks) only when theclock speed is lower than a predetermined rate. This is becausehyperlinks to tiles, which are normally two or more hops away in a twodimensional (east, west, south, north) mesh network, will traverselonger data paths. Data that traverses a longer data path will takelonger to reach its destination. Therefore, in some cases, these longerdelays limit the integrated circuit 100 to operating with slower clockspeeds when hyperlinks are used than the clock speeds that may beavailable when hyperlinks are not used. In some implementations, theclock speed of the integrated circuit 100 is itself controlled by one ormore mode indicators.

3.3 Reconfigurable Logic

As described above, a tile 102 can include Reconfigurable Logic (RL)that is able to perform reconfigurable bit-level (or “gate-level”) logicoperations or multi-bit-level logic operations. RL enables each tile tohave highly dense logic implemented in an energy efficient manner. Forexample, logic operations can be performed to implement functions suchas memory controllers in the tiles without needing to expend many cyclesto perform simple bit-level logic operations such bit shifts. The RLenables the integrated circuit 100 to perform more logic operations in asingle clock cycle in a way that is selectable at compile time by a useror in a way that is customizable to an application. FIGS. 5A-5F showexemplary configurations for including RL 500 in a tile 102.

Referring to FIG. 5A, the RL 500 is an adjunct to the processor 200. Inthis configuration, a user may define special instructions in a hardwaredescription language (e.g., verilog) for the RL 500. The RL 500 is ableto operate on a value from a register in the processor 200 and write theresult back into a register in the processor 200.

Referring to FIG. 5B, the RL 500 includes one or more connections to theswitch 220. The connections can include independent bit-levelconnections. Through the switch 220, the RL 500 is able to connect to RLof other tiles, so that the RL in multiple switches can be “gangedtogether” to perform operations cooperatively. The RL 500 can alsoinclude connections to the processor 200. The connections between the RL500 and the RL of other tiles can go through pipeline registers andmultiplexers so that the compiler software can orchestrate the RLoperations.

Referring to FIG. 5C, the tile 102 includes a multiplexer 502 thatselects data for a switch input buffer 503 from either the processor 200or the RL 500 based on a selection signal S_(i). The selection signalS_(i) is generated from decode logic 504 that decodes an instructionfrom the instruction memory 204. The logic-level instructions forconfiguring the RL can come from the processor 200, from a separate FIFOshift register (that can operate at a slow clock speed), from the staticor dynamic network, or from memory on the tile using load-storeinstructions. The RL takes input from an input register 508 and providesa result to an output register 510. Data from the switch 220 can also beprovided to either the processor 200 or the RL 500.

Referring to FIG. 5D, RL 500 is included in a switch 220 as optionaldata processing logic. A multiplexer 512 in the switch 220 is able toselect whether RL 500 operates upon data to be provided to an outputbuffer 514.

Referring to FIGS. 5E and 5F, RL 500 is optionally included at theboundary of the integrated circuit 100 FIG. 5E shows RL 500 between thearray of tiles 101 and a serial interface 514. In this example, the GRL500 connects to the switch of a tile at the edge of the array 101. FIG.5F shows RL 500 providing an interface to an on-chip memory 516 forstoring, e.g., configuration information.

Other configurations are possible for including RL 500 in a tile 102.For example, RL can be included in the processor pipeline 208 andconfigured to perform various operations on operands (e.g., the RL canbe configured as an ALU).

The operation of the RL can be configured based on logic-levelinstructions stored in a memory loaded by the processor 200, or based onmode information stored in a register loaded by the processor 200, forexample.

3.4 Direct Memory Access

The static and dynamic networks transport data among buffers in theswitches. The buffers are used as first-in-first-out (FIFO) queues thatare able to pour data into various sinks on the tile, or receive datafrom various sources on the tile. The processor 200 on a tile can be asource or sink of data to or from a buffer in the switch in the sametile or in a neighboring tile. For example, a buffer can be coupled to aregister that the processor 200 can write to or read from. In somecases, a processor 200 may read a data word from the switch buffer andexecute an instruction to store that data word in memory (e.g., eitherin a local cache in the tile, or in a memory external to the tiles 102via the dynamic network).

In other cases, a larger amount of memory (e.g., multiple words) mayneed to be stored in memory. Using a direct memory access (DMA)approach, a block of data including multiple words can be stored inmemory without requiring the processor to execute an instruction tostore each word of the data (or each segment of data greater than acache line). The processor executes one or more instructions to set upthe DMA transfer for outgoing DMA. For example, the processor writes astart address and an end address of the data block to be transferredinto one or more registers. Alternatively, the processor writes a startaddress and the size of the data block into registers.

A DMA controller in the tile transfers the data in the backgroundwithout processor intervention, enabling the processor to execute otherinstructions during the DMA transfer. At other tines, such as during acache miss, the size of data that is sent into the cache of a tilewithout processor intervention is limited to one cache line (e.g.,around 16 to 128 bytes). The size of the data block transferred in a DMAtransfer can be much larger than a cache line (e.g., 4 Kbytes). This DMAapproach can be indicated by control information within the data (e.g.,the data can contain a DMA tag that determines whether the data isdestined for a register (to be handled by the processor 200), or fordirect memory transfer. In the static network, the tag can be appendedto the data. In the case of the dynamic network, since the data is inthe form of a packet with a header, the tag can be included in theheader.

If the DMA tag is set, the data arriving at the switch of a destinationtile is deposited into a DMA queue and the data is passed directly intoa cache or static memory without involving the processor 200. If the DMAtag is not set, the data is put into a FIFO coupled to the registers ofthe processor 200. The value of this twofold processing is that when thedata is to go into memory, the processor does not have to be involved inthe receipt of the data. The DMA tag is set by the sender of the data.

In an alternative implementation, the DMA tag is not contained in thedata (or its header), rather there is a mode indicator called the DMAmode indicator in the appropriate network port (or in the tile). If thisDMA mode indicator is set, then the data is directed to memory.

3.5 Multiple Processor Instruction Streams

There are a variety of ways in which a tile 102 is able to processmultiple instruction streams. A tile 102 is able to process aninstruction stream for the processor 200 and an instruction stream forthe switch 220. In the operand decoupling mode described above, theswitch 220 processes multiple instruction streams (e.g., derived from amacro instruction stream) using multiple program counters to switch datafor multiple output ports independently. These separate processor andswitch instruction streams provides a form of concurrency in which atile can execute computations and switch data in the same clock cycle.

In another form of concurrency, some or all of the tiles can include aprocessor 200 that is configured to process multiple instructionstreams. The multiple instruction streams can be derived from a commonmacro instruction stream such as in a VLIW processor, or can be providedas separate threads. The processor 200 can include multiple logic unitsthat process a corresponding one of the instruction streams, based on acommon program counter as in a VLIW processor, or based on separateprogram counters as in a multithreaded processor. The processor 200 canalso include multiple register files each associated with acorresponding one of the instruction streams. These multiple processorinstruction streams provide a form of concurrency in which a tile canexecute multiple computations in same clock cycle.

The multiple logic units can include, for example, one or more of anarithmetic logic unit, an arithmetic unit, a multiply accumulate unit, amultiply add unit, a vector unit, a load or store unit, or a branchunit. The logic units can also include units that interact with theswitch, such as a switch read unit, which reads data received by theswitch, or a switch write unit, which stores data that is to be sentover the switch. For example, a switch write unit can include a FIFObuffer or a register.

In the case of a VLIW processor, the processor 200 is configured toexecute instructions taking into account interactions with the switch220. For example, the subinstructions of a VLIW instruction are executedtogether; therefore, if some subinstructions are reading from or writingto a port of the switch, the processor may need to stall execution ofthe VLIW instruction if a subinstruction is temporarily unable to readfrom or write to a port of the switch. FIG. 6A shows an example of atile 102 including a VLIW processor 200A having n ALUs (ALU(1)-ALU(n))that operate based on a common program counter 602.

There can be a long latency associated with certain tasks such asaccessing memory, sending data across the network, an synchronizingmultiple tiles. When one thread of a multithreaded processor isexecuting an instruction involving one of these tasks, another threadcan perform another task so that the latency associated with those tasksare overlapped. FIG. 6B shows an example of a tile 102 including amultithreaded processor 200B having n program counters (PC(1)-PC(n)) andn register files (Reg(1)-Reg(n)) that can be selectively coupled to anALU 604 so that when one thread is waiting on a long latency event, theprocessor 200B switch to a new thread in a new context, characterized bya different program counter and register file.

A switch processor can also be a VLIW processor 304B or a multithreadedprocessor 304C, as shown in FIGS. 6C and 6D, respectively.

When a compiler partitions a program into subprograms to execute in atiled integrated circuit having VLIW or multithreaded processors in thetiles, the compiler generate parallel code for a maximum number ofthreads larger than the number of tiles in the integrated circuit 100(e.g., up to four times the number of tiles if each tile has a VLIWprocessor with four subinstructions).

In the partitioning phase, the compiler partitions a program into setsof instructions that are able to be executed in parallel. For example,the compiler uses a graph to indicate which instructions can be executedin parallel. In the placement phase, the compiler maps the sets ofinstructions to tiles. The compiler determines in which tile each of thesets of instructions is to be executed is based in part on critical pathinformation from the graph to determine which instructions to run in thesame tile, and which to run in separate tiles. One or more of these setsof instructions selected to run within the same tile represent asubprogram for the tile.

Thus, a subprogram for a tile may include multiple sets of instructionsthat can be executed in parallel threads within the tile. For example,in a VLIW processor, for those sets of instructions selected to executeon the same tile, the compiler determines instructions within the setsof instructions that will run in parallel in the same VLIWmacroinstruction. The compiler determines instructions for amacroinstruction based in part on information characterizing whichfunctional units (e.g., ALUs) are available to be used in parallel toexecute a macroinstruction.

4 Dynamic Networks

As described above, the switches 220 include dynamic network circuitryfor routing packets of data based on a destination address in the headerof the packet. The payload of a packet includes a message or a portionof a message that is delivered to the tile at the destination address.Packets can have a fixed length, or a variable length. In one approachto variable length packets, a packet can vary in length from one wordplus a header word, up to 127 words plus a header word. The header wordcontains a field that determines the length of the packet.

The control module within a tile controlling the dynamic switch (e.g., adynamic switch processor) performs functions for transmitting, routing,and receiving packets. In some cases, the control module in a receivingtile processes multiple packets to recover a message that is larger thanthe maximum packet size. For example, the control module in thetransmitting tile segments the message among payloads of multiplepackets. The control modules in the tiles along a route between thesending and receiving tiles route the segments in the order in whichthey are received. The control module in the receiving tile reassemblesthe message. This segmentation and reassembly can be controlled by acommunication protocol in software running in a dynamic switch processorof a transmitting or receiving endpoint tile, or in software running inthe tile's main processor 200. In other cases, the atomicity afforded todata by packetization enables data associated with an atomic transactionto be transmitted in the payload of a single packet to ensure that thedata will not be interrupted by other packets.

The tiles can include circuitry for multiple independent dynamicnetworks. The different dynamic networks can each be dedicated tohandling a particular type of traffic. For example, one dynamic networkhandles traffic associated with a user, called the User Dynamic Network(UDN). Another dynamic network handles traffic associated with theoperating system and is primarily used to communicate with input andoutput devices, called the Input/Output Dynamic Network (IODN). Anotherdynamic network handles enables tiles and I/O devices to interface withcopious memory (e.g., DRAM coupled to the network), called the MemoryDynamic Network (MDN).

In one approach to deadlock recovery, described in more detail below,the MDN is used in a specific manner to guarantee that deadlock does notoccur on the MDN. The MDN is also used for inter-tile memory traffic(e.g., to a tile's data cache). Data can be coupled to the MDN by theprocessor 200 in the tiles, or by a DMA interface in the tiles. The DMAinterface can be coupled to one or more of the other networks as well.

The control module handles routing data from a sender to a receiver.Routing includes processing a destination identifier to determine aroute the data should traverse to the receiver. In some implementations,the dynamic networks have a two-dimensional topology and usedimension-ordered worm-hole routing. The dimension-ordered nature of thenetworks means that packets on the network follow a deterministicrouting path, for example, first along the “x” dimension (e.g.,East/West) and then along the “y” dimension (e.g., North/South) in atwo-dimensional network.

FIG. 7 shows the path 700 taken by a packet sent from the tile atcoordinates (1,2) to the tile at coordinates (5,6). As in the staticnetwork, each clock cycle one word of data traverses a link from onetile to a neighboring tile. The head word of the packet (e.g., theheader) worms through the network and reserves links between theintermediary switches along the route. Subsequent words of the packet upto the tail word continue to worm through the network along the samepath set up by the head word. The tail of a packet worms through thenetwork and clears the path for use by other packets. As the tailtraverses the network, it clears up a path for other packets to usereserved links. Wormhole networks are named as such because packetsappear to worm through the network. One reason that wormhole networksare advantageous is that they reduce the amount of buffer space neededin the switches.

A packet reaches its destination when both the x and y coordinates matchthe coordinates of the destination tile (e.g., stored in a registerloaded when the system boots). Alternatively, the packet header cancontain the number of hops in the x dimension as a Δx count and thenumber of hops in the y dimension as a Δy count. In this scheme, thevalue of Δx is decremented after each hop in the x dimension, and thevalue of Δy is decremented after each hop in the y dimension, and thepacket reaches its destination when Δx and Δy become 0. The packet isthen sent to a final destination port (also indicated in the packetheader) to the north, east, south, west, or into the processor. Thisfinal destination routing enables data to be directed off of the networkto an I/O device or memory interface, for example.

4.1 Local Link-Level Flow Control

Reliable data delivery is achieved in the dynamic network using flowcontrol to ensure that data is not lost or dropped when being routed inthe network. Local or “link-level” flow control ensures that data islost or dropped over a link between two tiles (e.g., due to limitedbuffering at a switch). Global or “end-to-end” flow control is used tofurther control the rate of data delivery between a sending tile (the“sender”) and a receiving tile (the “receiver”), and is described inmore detail below. Link-level flow control is not in general sufficientto provide end-to-end flow control due to the possibility of deadlock,(in this case, for example, due to limited buffering at a receiving tileat the end of a route) also described in more detail below.

One aspect of flow control includes managing the dynamic switch inputbuffers. Backward pressure is used to prevent a sending switch fromsending further data if the input buffer at the receiving switch isfull. This type of flow control is also called “backward flow control.”

A first approach to implementing link-level flow control includes asignal sent from the receiver to the sender (e.g., over a dedicatedwire) indicating that a particular input buffer is full, and that thesender should not send more data over the link. This “full signal”should be generated and sent to the sender quickly to reduce the delayin the critical path of link-level flow control.

A second approach to implementing link-level flow control is acredit-based approach. In this approach, the sender does not need toreceive a signal from the receiver that buffer space is available (thebuffer is not full) each time data is sent. In the credit-basedapproach, each sender maintains a count of the remaining space in thereceiver's input buffer. As data is sent over a link, the senderdecrements the count. When the count reaches zero, there is no morespace in the input buffer and the sender is barred from sending dataover the link. As data is read out of the input buffer, the receiversends credits to the sender. The sender increments the count for eachcredit received.

In the credit-based approach, dynamic switch circuitry can be pipelinedand can maintain full speed switch throughput. The size of the inputbuffer and associated credit counter are selected appropriately toaccount for the latency needed to send a credit from the receiver to thesender and to determine whether to send any further credits.

Referring to FIG. 8, switching circuitry 800 for a credit-based approachswitches data among input buffers that each store up to 3 words of datacorresponding to the arrangement of pipeline registers 801. Theswitching circuitry 800 is a portion of the dynamic switch that controlsthe flow of data from a sender tile_b to a receiver tile_a. The sendertile_b includes a data multiplexer 802 that selects a data word frominput buffers 804 to send to the input buffer 806 of the receivertile_a, according to route information stored in a route register 808.The route information is generated based on the headers of incomingpackets. The sender tile_b includes an input buffer for each of thetiles to which it is connected (tile_a, tile_c, tile_d, tile_e, . . . ).However, since the switching circuitry 800 controls the flow of data totile_b, the data multiplexer 802 does not necessarily need to be able topull data from tile_b. Corresponding circuitry is used to control theflow of data from the sender tile_b to other tiles to which tile_b isconnected.

Control circuitry 810 counts credits in a credit counter 812corresponding to input buffer space available in the receiver tile_a. Ifthere is at least one credit and an input buffer has data to be sent,the control circuitry 810 will assert a signal to dequeue data from theappropriate one of the input buffers 804 and enqueue the data to theinput buffer 806. Otherwise the control circuitry 810 will stall, notsending any data to the receiver tile_a.

The credit counter 812 tracks available storage space in the inputbuffer 806 to ensure that the input buffer 806 will not overflow.However, the number of credits stored in the credit counter does notnecessarily correspond to the actual amount of available buffer space inthe input buffer 806 at that time since the control circuitry accountsfor data that may flow into the input buffer 806 from pipelineregisters.

4.2 Deadlock Strategies

Deadlock is the inability for an entity to make forward progress due tothe dependence of a chain of resources or required actions thatultimately depend on the entity itself yielding a resource or takingsome action. In effect, deadlocks can be thought of as chains ofdependent resources or actions that contain cycles. This property ofdeadlocks can be quite instructive when used as a manner to detectdeadlocks. Thus, one approach to detecting deadlocks includes staticallyanalyzing a network or protocol and showing that cycles do not occur ingraphs that describe the dependencies that need to be resolved toaccomplish any outcome.

In computer systems, deadlock is almost never a desirable outcome. Indynamic networks, deadlock is something that should be addressed inorder for the dynamic network to provide a guarantee that all packetssent on the dynamic network will be delivered. If a deadlock occurs in anetwork then it may not be possible for further data to be delivered.When the dynamic networks of the integrated circuit 100 usedimension-ordered routing, it can be shown that the dimension-orderedrouting protocol itself does not produce deadlocks. For example, it canbe shown that to successfully route a packet, a packet must obtainaccess to routing resources in the “x” dimension before obtainingresources in the “y” dimension. Thus, in dimension-ordered routing,there is no case where a packet needs to obtain a resource thatultimately depends on a resource that is currently being held by thatpacket. More formal proofs of the deadlock-free nature ofdimension-ordered routing can be found in the literature.

While dimension-ordered networks are deadlock-free with respect to thetransportation of packets, the use of a dimension-ordered network doesnot prevent higher-level deadlocks from occurring. For example,dimension-ordered wormhole routing can still produce high leveldeadlocks. High level deadlocks are caused by the users of the dynamicnetwork through the manner in which they utilize the network (e.g., dueto limited buffering space at a data sink).

There are different types of high-level deadlocks that can occur. Onetype is a communication dependent deadlock. Communication dependentdeadlocks contain a cycle in the dependency graph associated with acommunication pattern. This type of deadlock arises from design errorand can be resolved by redesigning the communication protocol that gaverise to the communication pattern. Another type of deadlock islimited-buffer deadlock, which would not occur if the network containedmore buffer space. For example, this type of deadlock can arise fromlink congestion due to dependencies introduced into a dependency graphby wormhole routing.

FIG. 9 shows an example of a communication pattern that deadlocks on anetwork with a given amount of buffer space, but does not deadlock on anetwork with a larger amount of buffer space. In this example, there aretwo independent sets of communication occurring. Tiles 102A, 102B, and102C are able to communicate using a first communication pattern in adeadlock-free manner; and tiles 102D, 102E, and 102F are able tocommunicate using a second communication pattern in a deadlock-freemanner. But, when these two communication patterns are intermixed, theybecome dependent on each other, introducing a cycle into an associateddependency graph.

In this example, suppose that tile 102A and tile 102D both launch apacket longer than the buffering space between them and theirdestinations into the network simultaneously. Tile 102A's packet isdestined for tile 102B and tile 102D's packet is destined for tile 102E.After receiving the first few words of the packets (and filling theirinput buffers), tiles 102B and 102E decide that they need to send apacket to tiles 102C and 102F, respectively, before completing thereception of their inbound packets. Unfortunately, due to the blockingnature of wormhole routed networks, the physical channels between 102Band 102C are already blocked by a packet from 102D to 102E. Likewise thepacket from 102E to 102F is blocked by the packet from 102A to 102B.Thus, the packet from 102E to 102F is dependent on the packet from 102Ato 102B, which is dependent on sending the packet from 102 B to 102C,which is dependent on the packet from 102D to 102E, which is dependenton sending the packet from 102E to 102F. Since the packet from 102E to102F is dependent on itself, a dependency cycle has occurred causingdeadlock.

In this example, it can be shown that if there were more buffer space inthe receiving tiles 102B and 102E, the originally launched packets couldbe completely stored in the input buffers, freeing the blockage andenabling the data to flow in a deadlock free manner. Similarly, thecommunication patterns chosen in this example are deadlock-free if runindependently (e.g., using separate resources).

4.2.1 Deadlock Avoidance

One way to handle communication dependent deadlocks in a dynamic networkis to institute a restricted usage policy for the network to avoidsituations in which deadlock would occur. A simplistic example ofdeadlock avoidance is to say that only one packet is allowed in thenetwork at any given time. However, this may be too restrictive and maynot achieve good performance.

Another form of deadlock avoidance is to enforce that the communicationpatterns can be separated into logical channels and arranged on thenetwork in a manner that does not allow two logical channels to use thesame physical channel (e.g., the same buffer space). This logicalchannel separation approach is a feasible design, but may require toomany physical channels for all of the logical channels that may be usedon any given network.

An example of logical channel separation approach is to have two logicaltypes of packets: requests and responses. These logical types are mappedonto physical channels such that requests can only utilize north andwest links in the network and responses can only utilize east and southlinks in the network.

A variant of the logical channel separation approach is called a virtualnetwork scheme. In this scheme, two or more virtual networks (e.g., arequest network and a response network) are implemented on a singlephysical network. This is done by implementing separate buffers (e.g.,request buffers and response buffers) for the two virtual networks. Onlyrequest packets can occupy the request buffers and only response packetscan occupy response buffers. The same set of physical channel wires areused by both request packets and response packets. In this scheme, onetype of packets (e.g., response packets) can bypass another type ofpackets (e.g., request packets) when the request packets are blocked andnot moving forward, by occupying buffers that are reserved for responsepackets.

Another form of deadlock avoidance is to guarantee that the network willbe cleared if, at any given time, all of the sending tiles stop sendingpackets. One way to accomplish this is to reserve sufficient storagespace in the tiles such that any packet sent into the network can betemporarily stored in the reserved storage space without filling theinput buffers in the network. Thus, if all of the tiles stop sendingadditional data words, the receiving tiles would ultimately completelydrain the network. An implicit assumption in this type of design is thatthe receive side buffering and draining is independent of sending intothe network or any unbounded time computation or handling. To implementthis approach, the network has the ability to signal a sending tile tostop sending additional words when the receiving tile's buffer is fullusing a credit based flow control system, an acknowledgment system, or anegative acknowledgment system.

The MDN uses a deadlock avoidance approach to guarantee thatcommunication dependent deadlock does not occur. In order to preventdeadlock, the MDN protocol is carefully designed to remove dependenciesand follows a request-reply protocol along with a credit based flowcontrol system which guarantees that all requests are sinkable inoff-network storage. This approach enables the MDN to provide adeadlock-free path to copious memory used in the buffer virtualizationapproach described below.

4.2.2 Deadlock Recovery

Another approach for handling deadlock is to allow limited-bufferdeadlocks to occur and provide a way to detect that a deadlock hasoccurred and recover from the deadlock. One way to recover fromlimited-buffer deadlock is to add more logical or “virtual” buffering tothe network. This does not necessarily require any more physical storagespace in the tile input buffers, but rather extra buffer space can bereserved in a copious memory source (e.g., on-chip or off-chip SRAM,DRAM, flash memory, or disk storage). The extra buffer storage space maybe within the tile if, for example, the copious memory source has cacheon the tile and the amount of memory needed does not spill to memoryoutside of the on-tile cache. One or more of the dynamic networks,including the UDN and IODN, can be a “recovery-based network” using thisapproach of deadlock detection and recovery. The path to the copiousmemory source is itself free from deadlock, for example, a network (theMDN) using deadlock avoidance. This way, if any of the recovery-basednetworks deadlocks, then then that network can be drained out to copiousmemory over the network that utilizes deadlock avoidance.

Before a deadlock recovery mechanism can be engaged, a deadlock needs tobe detected. Deadlock detection on a distributed fabric of tiles callsfor a distributed approach to detecting that a deadlock has occurred.For example, to detect deadlock, each tile contains a deadlock detectiontimer that counts how many cycles data words stay in the input bufferswithout making forward progress. When one or more of the countersreaches a software defined threshold, a suspected deadlock has occurredand a deadlock recovery process is triggered.

In one approach to deadlock recovery, a suspected deadlock triggers analert in the form of a deadlock interrupt delivered to the tile'sprocessor. When the processor is interrupted, software running on theprocessor removes the packets that triggered the alert and stores thepackets into copious memory. This approach to deadlock recovery,however, changes the semantics of receiving network data. Instead ofsimply receiving data from a network mapped port, a program running on atile would receive data from either the port or from memory, dependingon the deadlock recovery state.

Another approach to deadlock recovery avoids the need for a change insemantics of receiving network data by using buffer virtualization.Buffer virtualization circuitry is used to provide the same softwareinterface to the networks whether the data is coming from the networkinput buffers or from memory. For example, the software interface to thedynamic networks is provided through register mapped switch ports. Thesource of the data to these switch ports changes depending on when theswitch is in a “virtualized” versus “non-virtualized” mode.

Referring to FIG. 10, a dynamic network input buffer 1000 is fed intoone port of a multiplexer 1002. The other port of the multiplexer 1004is fed by a refill buffer 1006. The refill buffer 1006 can have one ormore entries each storing a word. The multiplexer 1004 provides data toa register mapped interface from either the input buffer 1000 or therefill buffer 1006, based on a refill signal 1008. Under non-virtualizedoperation, the refill buffer is empty and the packet data is provided tothe processor, or to switch output ports, from the input buffer 1000. Asdescribed below, after a deadlock is detected, data from the inputbuffer 1000 may be moved into a queue in copious memory. When the switchresumes reading data the refill signal 1008 is set and data is providedfrom memory via the refill buffer 1006 instead of from the input buffer1000. When the refill buffer becomes empty, and the refill signal 1008is still enabled, an interrupt 1010 signals that the refill buffer isempty and needs to be refilled from memory. If the queue in memory isempty then refill signal 1008 can be disabled and data can be read fromthe input buffer 1000 again. Thus, by using the multiplexer 1004, therefill buffer 1006, and refill signal 1008, an input buffer 1000 can be“virtualized” by using a queue in copious memory to appear as bufferspace in the network.

After a deadlock is detected, in order to recover from the deadlock, thedeadlock detection counter triggers an interrupt signaling that thenetwork has not moved for a predetermined period of time (set by thethreshold). At this point, an interrupt handler removes all of theinbound packets stored in the tile's input buffers and stores theircontents into memory. This memory may be in a cache in the tile or mayspill out into copious memory. If the data is sent to copious memory,the path to that memory is deadlock-free due to the deadlock avoidanceprotocol that the MDN utilizes. After data has been stored into memory,it is the responsibility of the interrupt handler to turn the particularinput port into virtualized mode and keep the refill buffer full untilthere is no more data destined for the particular input port stored inmemory. By providing a refill buffer that stores multiple data words,and loading multiple words into the buffer on an interrupt, the numberof interrupts taken can be reduced, improving performance. As the tilesremove packets and hence contention from the deadlocked network, trafficbegins to flow again. Multiple tiles may need to remove data from theirinput buffers to recover from limited-buffer deadlocks. Also, a singletile may have to trigger an interrupt multiple times to clear adeadlock.

4.3 Global End-to-End Flow Control

The dynamic networks are able to guarantee reliable delivery of data.Part of the ability to provide this guarantee comes from the locallink-level flow control. In addition to reliable delivery of packets,global end-to-end flow control is concerned with rate limitingcommunication between communicating endpoints in a network. Forward andbackward pressure are used to synchronize the rates at which data issourced into the network and sinked from the network. End-to-end flowcontrol enables a receiving tile to receive forward pressure from thenetwork if the sending tile has not sent any words to the receivingtile, and enables a receiving tile to apply backward pressure to notifya sending tile targeting a receiving tile that it is not capable ofaccepting any more data.

Simply providing link-to-link flow control is not in general sufficientto provide end-to-end flow control because deadlock can occur in thenetwork, as in the example above. Other mechanisms, such as credit-basedflow control, can be used to provide end-to-end flow control on adynamic network.

4.3.1 Credit-Based Flow Control

One manner to provide end-to-end flow control is to use long distancecredit-based flow control. The link-level credit-based flow controldescribed above operates between switches connected by a link. Theend-to-end credit based flow control described in this section operatesbetween a sender and receiver dynamic switches, which may have manyrouting dynamic switches between them. End-to-end flow control can beimplemented in hardware, or in software, or in a combination of hardwareand software.

In credit based flow control, a sending tile maintains a count of howmany buffer entries are free for its use for particular flow of data toa particular receiving tile. As the sending tile sends data, itdecrements the count until the count reaches zero indicating all of theremote buffer space has been utilized. The count reaching zero indicatesthat no more space is available and is a form or backward flow control.In a credit-based flow control approach, the receiving tile signals thesending tile that data has been dequeued from the input buffer to freeadditional storage space by sending an acknowledgment to the sendingtile denoting how much data has been dequeued from the input buffer.

If credit-based flow control is used and the sending tiles limit theamount of data injected into the network based on a known amount ofinput buffer space, then at any time, if the sending tiles were to stopsending, all of the in-flight packets would drain into the input buffersand the network would be clear. In effect, credit-based flow control isalso able to avoid deadlock. However, the amount of input buffer spacein the tiles can be small (e.g., on the order of a few words). Thus,buffer space can be a scarce resource, especially when there are manyflows targeting any given receiving tile. Thus, when the buffer space isdivided by the number of active flows targeting any tile, the number ofoutstanding words that a sending tile may send safely without receivingan acknowledgment may be small.

In one example, each link in a network transmits one word per cycle, apair sending and receiving tiles are separated by 20 links, and theinput buffer size is four words. The sending tile is able to send fourwords and then is stalled until an acknowledgement is received from thereceiving tile, which may be in the best case 20+20−4=36 clock cyclesafter sending the fourth word. This effectively reduces the rate atwhich the tiles can operate down to one tenth of its maximum possiblerate (4 words sent in 40 cycles). To sustain a maximum communicationrate between two tiles, the buffers need to be the size of thebandwidth-delay product, which is the amount of data sent across thenetwork before an acknowledgment is received.

The protocol that is used on the MDN includes credit-based flow controlwith pre-allocated buffering space in copious memory (or in specialbuffer memory at the endpoints either on-chip or off-chip) to avoiddeadlock. Each tile is allocated a certain amount of buffer space. Asdata is sent to the memory, an in-tile counter is decremented until allof the buffer space is utilized at which point the MDN stalls awaitingacknowledgments.

The UDN and IODN are capable of recovering from a limited-bufferdeadlock, but these networks may still benefit from limiting the rate ofdata flow. For example, a computation operated on a stream of data maybenefit by using flow control to limit an upstream data source. Anotherreason for end-to-end flow control on the UDN and IODN is to bound theamount of buffer space needed in copious memory for the deadlockrecovery queues.

4.3.2 Lazy Acknowledgment Protocol

When implementing credit based flow control, in general, some entity,whether it be software or hardware, generates acknowledgments. There areseveral ways to determine when to send acknowledgments. In one approach,on every word that is consumed at a receiver, the receiver sends anacknowledgment to the sender. In another approach, the receiver sends anacknowledgment to the sender after receiving a predetermined number ofwords. This acknowledgment coalescing is done to reduce the bandwidthneeded to support acknowledgments.

In an approach called the Lazy Ack Protocol (LAP), instead of puttingthe responsibility of determining when to send acknowledgments on thereceiving tile, the sending tile determines which packets are to beacknowledged. In one implementation of the LAP, the sender sets a tag ina header of a to request the receiver to respond with an acknowledgment.Thus, a sender is able to mark a packet as the one to be acknowledged.It is the receiver's responsibility to acknowledge all packets receivedthat have been marked as needing to be acknowledged. Utilizing the LAPcan significantly reduce the amount of bandwidth used by acknowledgmenttraffic because one strategically placed acknowledgment request canrepresent many words having been processed.

In order for the LAP to provide good performance, the sending tileshould request acknowledgments before the sending tile's credit countreaches zero. For example, the request should be generated with enoughcredits remaining for the resulting acknowledgment to arrive before thecredit count reaches zero. If the sender were to wait until the creditcount was near zero before requesting an acknowledgment, the senderwould stall for at least the round trip delay to and from the receiver.

4.3.3 Oversend Buffer Protocol

The deadlock recovery approach using buffer virtualization is able tostore a large amount of data in copious memory. Therefore, the UDN andIODN using deadlock recovery do not need to use credit-based flowcontrol to prevent overflow of the input buffers. Nevertheless, it maybe useful to use credit-based flow control, for example, to limit on theamount memory that could potentially be used in deadlock recovery.

As described above, for good bandwidth utilization in credit-basedsystems, the amount of input buffering per flow should be at least thesize of the bandwidth-delay product. However, this amount of physicalon-chip buffering space may be area prohibitive. Even if large amount ofinput buffer space were added at the expense of integrated circuitspace, this would aggravate the problem by pushing tiles further apartcausing longer latencies and requiring more buffering space.

To provide credit-based flow control with high bandwidth utilization andmodest input buffering requirements in the context of virtual buffering,an oversend buffer protocol (OBP) can be used. The OBP providescredit-based flow control that allows the sending tiles to assume thatthere is more input buffer space at the receiving tile than isphysically available. Thus in this approach, sending tiles may send moredata than is guaranteed to be stored in a receiving tile's input buffer.In the common case, where the receiving tile is reading from its inputbuffers in a timely manner, the network will continue to flow and thenetwork will not deadlock. The link-to-link flow control may impose someamount of rate limiting on the sending tile.

When the OBP is employed in a network using deadlock detection andrecovery, the deadlock detection timer that is watching the input buffercan be adjusted to a greater value. The more the amount of “oversending”(the amount by which the credit exceeds the input buffer size), the morethe threshold value of the deadlock detection timer can be increased.

The OBP may deadlock if the receiving tile does not expeditiously readfrom its input queue or there is a large amount of network traffic. Inthis case, the OBP utilizes the deadlock recovery mechanism to providevirtual buffering space in copious memory. The OBP can be thought of aseffectively providing a large virtual input buffer at each receivingtile dedicated to each inbound flow. This virtual input buffer is largerthan the dedicated physical input buffer and can be thought of asproviding part of the input buffer space in the on-tile cache or incopious memory and part in the physical input buffer.

Another benefit provided by the OBP is that the amount of storage spacein copious memory that could potentially be used is bounded.Furthermore, because the receiving tile's input buffer can bevirtualized through a cached memory system, there is a strong chancethat this virtual buffer space is actually stored in local cache in thetile and not in off-chip copious memory.

4.4 Network Interfacing

The dynamic networks can include features that facilitate coupling datato and from the processor, and that enable efficient handling ofincoming messages. Register mapped network interfaces, pipelineintegration (e.g., integration of a switch interface in pipeline bypasspaths), and receive side de-multiplexing are examples of such features.

4.4.1 Register Mapped Network Communication

As described above, dynamic networks are able to transfer data to andfrom the main processor through a register mapped interface. When themain processor reads a register corresponding to a particular network,the data is dequeued from the respective network input buffer. Likewise,when a register associated with a particular network is written by theprocessor, the data is directly sent out of a corresponding networkoutput port.

The register mapped networks are both read and write flow controlled.For instance, if the processor attempts to read from a registerconnected to a network and the data has not arrived yet, the processorwill stall in anticipation of the data arriving. Outbound datacommunication can also receive backward pressure from the networks toprevent it from injecting into the network if the network buffer spaceis full. In this case, the processor stalls when the outbound bufferspace is full for a particular network.

For efficient register mapped communication, the dynamic networks areintegrated closely into the processor's pipeline. In effect, theycontribute to the scoreboarding in the processor, and the processormaintains correct output ordering across variable length pipelines. Onepossible implementation of this register mapped communication is viaintegration of the input or output buffers into the bypass network ofthe processor pipeline. By doing so, for example, a value going out fromthe ALU in a pipeline can go to the switch on an immediately followingcycle, and well before the pipeline writeback stage (which is the“pipeline commit stage” in some pipelines) when the data value iswritten into the register file. In the case of the tiled integratedcircuit in which pipelines are coupled via a switch network, thepipeline commit stage is the earlier stage (generally earlier than thewriteback stage) in which a value can be injected into the network. Thisis called an early commit pipeline. Also, in order to reduce latency, itis desirable to expeditiously forward a value to the network as soon asthe value is computed. In order to accomplish this, an implementationmay contain a forwarding network which chooses the oldest completedinformation in the pipeline to forward out to the network.

The register mapped interface to the processor can include multipleregisters that are mapped not only to a particular input port, but tocharacteristics associated with inbound communication as described inmore detail in the following section.

4.4.2 Receive Side De-multiplexing

In a dynamic network, each tile can receive packets from a large numberof tiles. For many applications, the receiving tile needs to be able toquickly determine, for any message that it receives, which tile sent themessage. The dynamic networks can perform sorting or “de-multiplexing”of packets at a receiving tile into de-multiplexing queues. The incomingpackets can be sorted based on a tag, where the tag may represent thesending tile, a stream number, a message type, or some combination ofthese or other characteristics. A tile can optionally remove headers andtags such that only data is stored into the de-multiplexing queues.

In a software approach to receive side de-multiplexing each messagecontains a tag, and for each new message received, the receiving tiletakes an interrupt when a message arrives. (Alternatively, the receivingtile discovers there is a message by—possibly periodically—polling anincoming network queue and transferring control to a handler uponmessage discovery). The interrupt handler then inspects the tag anddetermines a queue in memory or cache into which the packet should beenqueued. When the tile wants to read from a particular sending tile (ora given tag), it looks into the corresponding queue stored in memory anddequeues from a particular memory stored queue. While this approach isflexible, the cost associated with taking an interrupt and implementingthe sorting based on inspecting the tag in software may be tooexpensive. Also, reading out of memory on the receive side is morecostly than reading directly from a register assuming that the tilecontains register mapped networks.

To accelerate receive side de-multiplexing, the dynamic networks includea sorting module that automatically sorts inbound packets into buffersthat act as the de-multiplexing queues. This hardware de-multiplexing isprovided to the register mapped processor interface to the dynamicnetwork. The interface between the de-multiplexing queues and the mainprocessor 200 is through register reads. For example, the processor 200reads from a register name mapped to one of the de-multiplexing queues,and the word at the head of that queue is dequeued and provided to theprocessor 200. Optionally, data from a de-multiplexing queue can be readwithout being dequeued. The interface can optionally use a memoryinterface in which the processor uses loads and stores.

FIG. 11 shows an implementation of a sorting module 1100 that providesdata to the processor from an input buffer 1102, the sorting module 1100includes one or more de-multiplexing queues 1104 that are eachconfigured to store data from the input buffer 1102 based on a tag inthe data. A catch-all queue 1106 stores data whose tag that does notmatch that of any of the de-multiplexing queues 1104 (a “tag miss”).Alternatively, the catch-all path from the input buffer 1102 can becoupled directly to the processor 200, bypassing the de-multiplexingqueues. Optionally, the sorting module 1100 can trigger an interrupt tothe processor 200 on a tag miss.

The number of de-multiplexing queues used by a given dynamic network canvary. For example, the UDN contains four hardware de-multiplexing queuesin addition to a catch-all queue. The IODN contains two hardwarede-multiplexing queues in addition to a catch-all queue. It may bebeneficial to provide a number of de-multiplexing queues that is a powerof two (e.g., 2, 4, 8, 16, etc.), such that each value of a multi-bitaddress corresponds to a de-multiplexing queue. In some implementations,if a circuit includes N tiles, each tile can include N de-multiplexingqueues. In such a configuration, each sending tile is guaranteed atleast one input queue at each potential receiving tile. In someimplementations, a dynamic network may have only one de-multiplexingqueue to separate data having a particular tag. Each of thede-multiplexing queues can be mapped into the processor's registerspace. To access the catch-all queue 1106, the processor can access aregister that is associated with catch-all processing.

Each de-multiplexing queue 1104 is virtualized, having a main buffer1110 and a refill buffer 1112 for providing data from a memory duringdeadlock recovery. A tag comparison module 1114 compares a tag stored ina tag register 1116 with a tag word of a packet as it is dequeued fromthe input buffer 1102. Alternatively, a tag can be distributed overmultiple words. Each subsequent word of the packet is processedaccording to the same tag. In some cases, a packet may have a singleword of data, and the tag is represented by a portion of that word.

4.4.2.1 De-Multiplexing Operation

During operation, each de-multiplexing queue contains an associated tagthat can be changed in software by writing to the associated tagregister 1116. Alternatively, the tags can be hard coded and a decodercan translate a tag in the data to one of the hard coded values.Hardcoded values can be, for example, 0, 1, 2, 3 and so on. For suchvalues, the decoding of the tag becomes a simple indexing operationusing the tag (with values, 0, 1, 2, or 3, for example) into a smallmemory array. Referring to FIGS. 11 and 12, the switch 220 firstexamines the header word 1200 of a packet in the input buffer 1102 todetermine whether the packet destined for the processor of that tile. Ifso, the header can be removed and the tag and data passed to the sortingmodule 1100 in the tile. If not, the packet is routed out of theappropriate output port of the dynamic switch. The word following theheader is the tag 1202. The sorting module 1100 compares the tag 1202 tothe tag stored in the tag register 1116. If a match occurs, the tag isremoved and the payload words 1204 of the packet are enqueued into theassociated main buffer 1110 of the de-multiplexing queue 1104. If noneof the stored tags match the packet's tag, the packet is routed into acatch-all data buffer 1118 of the catch-all queue 1106. The catch-allqueue 1106 also includes a buffer 1120 to store the tag associated withthe packet, a buffer 1122 to store the total length of the packet, and abuffer 1124 to store the length remaining in the current packet. Thismeta-data buffers use the same tag-miss control signal 1126 as thecatch-all data buffer 1118. This meta-data is used to determine what tagand packet length is associated with each data word. The catch-all queue1106 is also mapped to registers that can be read by the processor.Since multiple packets with differing tags can reside in the catch-allqueue 1106, the processor uses this meta-data to distinguish one packetfrom another. The processor can optionally sort these packets not beinghandled by the hardware tagged de-multiplexing queues 1104 into softwaremanaged de-multiplexing queues (e.g., in on-tile cached memory).

The dynamic network's catch-all handling hardware is capable ofsignaling an interrupt on receipt of data. The receiving processor 200can be configured to signal an interrupt on receipt of data to thecatch-all queue 1106 by configuring special purpose registers.Alternatively, the data can be received by having the processor 200 pollthe catch-all queue 1106. This configurability supports both a pollingand interrupt model for packets with tags that are not currentlyassigned.

4.4.2.2 Managing Tags

Tags provide a namespace for different flows of data. The tag namespacedoes not need to be global across all tiles. Rather, the tag namespacecan be specialized for different tiles. The usage, allocation, andmanagement of tags can be controlled by software. For example, thecompiler or programmer is able to manage the tag namespace and allocatetags. Possible allocation models for the tag space include a staticmapping, a mapping that denotes the sending tile, a mapping where a tagdenotes a flow of data, or a mapping where a tag is a one-time entity.Software is also able to determine what tag is currently present in thetag registers 1116 at any given time.

Another aspect of managing tags is the process of modifying residenttags and the semantics of updating a tag register 1116 while the tile isoperating. To begin with, the sorting module 1100 can be stalled basedon the value of a mode indicator. Modifying tags while the sortingmodule 1100 is still operating could lead to unpredictable results. Eventhough the sorting module 1100 can be stalled, care must still be takenwhen modifying the tag registers 1116 due to the atomic packet basednature of the dynamic networks.

When the sorting module 1100 is stalled, input buffer 1102 continues toreceive data, but no new data will enter or leave the de-multiplexingqueues 1104 or catch-all queue 1106. While the sorting module 1100 isstalled, it is safe to change tags stored in the tag registers 1116.When the sorting module 1100 resumes operation, messages begin to flowinto the appropriate queues.

Care should be taken in the case where a packet has been partiallysorted, but not in its entirety. In this case, the atomic unit of apacket has been partially sorted into a de-multiplexing queue 1104 orcatch-all queue 1106, while the later portion of the packet is stillwaiting to be sorted. In order to address this scenario, when changingtags for packets that are in-flight special care should be taken.

The sorting module 1100 includes circuitry for detecting the state ofthe de-multiplexing queues 1104 and the catch-all queues 1106 toidentify when a packet is partially sorted. For example, the state ofthe catch-all queue 1106 can be determined by comparing the values inthe buffer 1122 storing the total length of the packet and the buffer1124 storing the length remaining in the current packet. When updating atag in the tag register 1116 of a de-multiplexing queue 1104 which isassociated with a packet that is not completely sorted, the queue inwhich the packet is stored is emptied and that queue is placed into thecatch-all queue, or it is “virtualized” in memory (i.e., stored intomemory) to be read out from the refill buffer 1112. This way, the datafrom the old tag is received through the catch-all queue or throughmemory (virtualized), and the data from the new tag is received from theregister mapped de-multiplexing queue 1104.

When multiple tiles share the same name space for tags, a “barriersynchronization” technique is used to ensure that all of the tilesharing the name space are able to coordinate changes to tags. Forexample, before a tag is updated, the processors in the tiles execute abarrier synchronization operation to indicate that new tag names will beused. A compiler (or a programmer) ensures that all processors executethe barrier synchronization operation at the appropriate time tocoordinate the change in tag names with execution of the barriersynchronization operation.

4.4.2.3 Using Tags

There are several ways in which de-multiplexing tags can be added to apacket. A tag can be added to a message to be sent in a packet insoftware by a process that is running in the transmitting tile. Forexample, the processor executes an instruction to write tag data alongwith the packet data to be sent into the network. The encodedinstruction can specify a tag to be used along with other headerinformation associated with a message, such as an operand value foranother tile. An exemplary add instruction for adding the values A andB, and sending the result over the network is:

-   -   add targetC, d, t, A, B

In this instruction, A is added to B and the result is inserted into aregister mapped output buffer named targetC to be sent to a destinationd with a tag of t. In a multi-issue processor, such as a VLIW processoror superscalar processor, multiple tags and destinations can bespecified in each instruction.

Another way that a tag may be added to a packet is by circuitry in thetile configured to attach tags to packets. For example, the processor200 accesses a special purpose register associated with each outputbuffer 232B of a register mapped switch interface 232. The specialpurpose register can provide various type of overhead information for amessage to be sent into the network in a packet, includingde-multiplexing tag, destination location for routing, and messagelength. After the processor 200 writes the message data into theregister mapped output buffer and the overhead information into thespecial purpose register, and the message would automatically beinjected into the network with the appropriate de-multiplexing tag andheader.

The information stored in the special purpose registers can also be usedfor repeated messages sharing the same overhead information, such asde-multiplexing tag, source and destination address, and message length.By including a special purpose register and other specialized hardwarein a tile to facilitate tag addition and message dispatch, the processor200 can be freed to perform other computation while a message isinjected into the network. This is especially useful for short (e.g.,single word) messages because they can be sent without the processingoverhead of constructing a header for each message in a related seriesof messages (e.g., scalar operands).

In some cases, it is useful for a path from a given source to a givendestination to be the same for successive values. This is especiallyuseful when instruction level parallelism (ILP) is being mapped across anumber of processors connected by a network. When exploiting ILP,ordering is important for values being received. If a dynamic networkpreserves ordering of packets sent between any two tiles, but does notguarantee ordering of packets received at a tile from different senders,receive side de-multiplexing circuitry enables an efficient scheme fordetermining the sender of a packet and sorting the packets by sender(e.g., without having to read the packet header in software). In thiscase, the tags that are used to sort packets can be assigned by acompiler to identify each sending and receiving pair of tiles.

Referring to FIG. 13A, multiple communicating processes 1300A-1300F areeach mapped to a processor in a different tile and the communicationbetween processes flows over a dynamic network. In this example,processes 1300B, 1300D, and 1300E are all sending messages to process1300C. Without receive side de-multiplexing circuitry, process 1300Cwould need to expend processor time to determine which process anyincoming message was coming from. With receive side de-multiplexingcircuitry, each of the processes 1300B, 1300D, and 1300E are able to tagany messages that they send to process 1300C with different tags (e.g.,x, y, z, respectively) to denote their specific flows. Process 1300Cconfigures its receive side de-multiplexing circuitry to automaticallyde-multiplex the messages into independent queues that can quickly beread on the processor on which process 1300C is running.

Receive side de-multiplexing can also support multiple flows between twonodes. Receive side de-multiplexing can de-multiplex not only flows frommultiple tiles to one receiving tile, but multiple flows of traffic fromone tile to a singular other tile. FIG. 13B shows an example in whichprocess 1300B is sending two independent flows over a dynamic networkwith hardware de-multiplexing to process 1300C. These two flows aretagged w and x, respectively.

Dynamic networks with receive-side de-multiplexing can also be used withstreams built on top of dynamic message packets. With the addition ofreceive side de-multiplexing, it is possible to implement long-livedpersistent streams of data between communicating tiles. If thecommunication channels are streams of values, the streams will bepacketized when sent over the network. With efficient receive sidede-multiplexing and automatic removal of headers and tags by thede-multiplexing circuitry, packetization is transparent to the receiver.

When utilizing receive side de-multiplexing, a programmer, automatedtool, or compiler may determine that all of the dedicatedde-multiplexing queues have been used at a particular receiving tile (a“full tile”), but another tile which is already communicating with thefull tile has available queue space (an “available tile”). If third tileneeds to communicate with the full tile, it is possible that node underthe direction of a programmer, automated tool, or compiler, the thirdtile can send its messages destined for the full tile to the availabletile already communicating with the full tile. Then the available tilecan proxy that message onto the full tile for the third tile.

Various features of the tiled integrated circuit architecture andprogramming described herein can be implemented by modifying versions ofthe tiled integrated circuits described in the following publications:“Baring It All to Software: RAW Machines” IEEE Computer, September 1997,pp. 86-93, “Space-Time Scheduling of Instruction-Level Parallelism on aRaw Machine,” Proceedings of the Eighth International Conference onArchitectural Support for Programming Languages and Operating Systems(ASPLOS-VIII), San Jose, Calif., Oct. 4-7, 1998, “Raw Computation”Scientific American, August 1999, Vol. 281, No. 2, pp. 44-47, “The RawMicroprocessor: A Computational Fabric for Software Circuits and GeneralPurpose Programs,” IEEE Micro, March/April 2002, pp. 25-35, and “A16-issue multiple-program-counter microprocessor with point-to-pointscalar operand network,” Proceedings of the IEEE InternationalSolid-State Circuits Conference, February 2003, each of which isincorporated herein by reference.

It is to be understood that the foregoing description is intended toillustrate and not to limit the scope of the invention, which is definedby the scope of the appended claims. Other embodiments are within thescope of the following claims.

1. An integrated circuit comprising: a plurality of tiles, each tilecomprising a processor; a switch including switching circuitry toforward data over data paths from other tiles to the processor and toswitches of other tiles; a first buffer that stores data from theswitch; a memory accessible to the processor; a second buffer thatstores a plurality of data words retrieved from the memory; and amultiplexer that selectively provides data to the processor from thefirst buffer or the second buffer based on a refill signal thatindicates one of multiple modes of operation, with, in a first mode ofoperation data words that have been received by the switch being storedin the first buffer and the multiplexer providing the data words to theprocessor from the first buffer, and in a second mode of operation datawords that have been moved from the first buffer to the memory beingretrieved from the memory and stored in the second buffer and themultiplexer providing the data words to the processor from the secondbuffer.
 2. The integrated circuit of claim 1, wherein the memory isinternal to the tile.
 3. The integrated circuit of claim 1, wherein thememory is external to the tile.
 4. The integrated circuit of claim 1,wherein the tile is configured to load the second buffer with additionaldata retrieved from the memory after the multiplexer provides datastored in the second buffer to the processor.
 5. The integrated circuitof claim 1, wherein the tile is configured to load the second bufferwith additional data retrieved from the memory after the second bufferbecomes empty.
 6. The integrated circuit of claim 5, wherein aninterrupt to the processor is triggered when the second buffer becomesempty.
 7. The integrated circuit of claim 1, wherein the tile isconfigured to set the value of the refill signal so that the multiplexerprovides the processor data from the first buffer in response to thesecond buffer providing a last data value retrieved from the memory. 8.The integrated circuit of claim 1, wherein the tile is configured to setthe value of the refill signal so that the multiplexer provides theprocessor data from the second buffer in response to the first bufferoverflowing to the memory.
 9. A method for transmitting data in anintegrated circuit, the integrated circuit comprising a plurality oftiles, each tile comprising a processor, and a switch includingswitching circuitry to forward data over data paths from other tiles tothe processor and to switches of other tiles, the method comprising:storing data from the switch in a first buffer; storing a plurality ofdata words retrieved from a memory accessible to the processor in asecond buffer; and selectively providing data to the processor from thefirst buffer or the second buffer based on a refill signal thatindicates one of multiple modes of operation, with, in a first mode ofoperation data words that have been received by the switch being storedin the first buffer and the multiplexer providing the data words to theprocessor from the first buffer, and in a second mode of operation datawords that have been moved from the first buffer to the memory beingretrieved from the memory and stored in the second buffer and themultiplexer providing the data words to the processor from the secondbuffer.
 10. The method of claim 9, wherein the plurality of data wordsare retrieved from a memory internal to the tile.
 11. The method ofclaim 9, wherein the plurality of data words are retrieved from a memoryexternal to the tile.
 12. The method of claim 9, further comprisingloading the second buffer with additional data retrieved from the memoryafter the multiplexer provides data stored in the second buffer to theprocessor.
 13. The method of claim 9, further comprising loading thesecond buffer with additional data retrieved from the memory after thesecond buffer becomes empty.
 14. The method of claim 13, furthercomprising triggering an interrupt to the processor when the secondbuffer becomes empty.
 15. The method of claim 9, further comprisingsetting the value of the refill signal so that the multiplexer providesthe processor data from the first buffer in response to the secondbuffer providing a last data value retrieved from the memory.
 16. Themethod of claim 9, further comprising setting the value of the refillsignal so that the multiplexer provides the processor data from thesecond buffer in response to the first buffer overflowing to the memory.17. The integrated circuit of claim 7, wherein the plurality of datawords retrieved from the memory were stored in the memory from the firstbuffer.
 18. The integrated circuit of claim 17, wherein the plurality ofdata words retrieved from the memory were stored in the memory from thefirst buffer in response to detection of a deadlock.
 19. The integratedcircuit of claim 18, wherein the detection of the deadlock includes thefirst buffer overflowing to the memory.
 20. The integrated circuit ofclaim 19, wherein the tile is configured to set the value of the refillsignal so that the multiplexer provides the processor data from thesecond buffer in response to the first buffer overflowing to the memory.21. The integrated circuit of claim 18, wherein the tile is configuredto set the value of the refill signal so that the multiplexer providesthe processor data from the second buffer in response to the detectionof the deadlock.
 22. The integrated circuit of claim 21, wherein theplurality of data words retrieved from the memory were stored in a queuein the memory.
 23. The integrated circuit of claim 22, wherein the tileis configured to set the value of the refill signal so that themultiplexer provides the processor data from the first buffer inresponse to the queue in the memory being empty.
 24. The integratedcircuit of claim 1, wherein the tile is configured to set the value ofthe refill signal to switch from the first mode of operation to thesecond mode of operation in response to the first buffer overflowing.25. The integrated circuit of claim 24, wherein, when switching from thefirst mode of operation to the second mode of operation, data wordsstored in the first buffer are moved to a queue in the memory.
 26. Theintegrated circuit of claim 25, wherein the tile is configured to setthe value of the refill signal to switch from the second mode ofoperation to the first mode of operation in response to the secondbuffer providing to the processor a last data value retrieved from thequeue in the memory.
 27. The integrated circuit of claim 26, wherein,operations performed by the processor to interface to the switch in thefirst mode are the same as operations performed by the processor tointerface to the switch in the second mode so that a software interfaceto the switch does not depend on whether the first buffer has overflowedto the memory.
 28. The integrated circuit of claim 1, wherein,operations performed by the processor to interface to the switch in thefirst mode are the same as operations performed by the processor tointerface to the switch in the second mode so that a software interfaceto the switch does not depend on whether the first buffer has overflowedto the memory.